#include <xrpld/app/rdb/Wallet.h>

#include <boost/format.hpp>

namespace ripple {

std::unique_ptr<DatabaseCon>
makeWalletDB(DatabaseCon::Setup const& setup, beast::Journal j)
{
    // wallet database
    return std::make_unique<DatabaseCon>(
        setup, WalletDBName, std::array<std::string, 0>(), WalletDBInit, j);
}

std::unique_ptr<DatabaseCon>
makeTestWalletDB(
    DatabaseCon::Setup const& setup,
    std::string const& dbname,
    beast::Journal j)
{
    // wallet database
    return std::make_unique<DatabaseCon>(
        setup, dbname.data(), std::array<std::string, 0>(), WalletDBInit, j);
}

void
getManifests(
    soci::session& session,
    std::string const& dbTable,
    ManifestCache& mCache,
    beast::Journal j)
{
    // Load manifests stored in database
    std::string const sql = "SELECT RawData FROM " + dbTable + ";";
    soci::blob sociRawData(session);
    soci::statement st = (session.prepare << sql, soci::into(sociRawData));
    st.execute();
    while (st.fetch())
    {
        std::string serialized;
        convert(sociRawData, serialized);
        if (auto mo = deserializeManifest(serialized))
        {
            if (!mo->verify())
            {
                JLOG(j.warn()) << "Unverifiable manifest in db";
                continue;
            }

            mCache.applyManifest(std::move(*mo));
        }
        else
        {
            JLOG(j.warn()) << "Malformed manifest in database";
        }
    }
}

static void
saveManifest(
    soci::session& session,
    std::string const& dbTable,
    std::string const& serialized)
{
    // soci does not support bulk insertion of blob data
    // Do not reuse blob because manifest ecdsa signatures vary in length
    // but blob write length is expected to be >= the last write
    soci::blob rawData(session);
    convert(serialized, rawData);
    session << "INSERT INTO " << dbTable << " (RawData) VALUES (:rawData);",
        soci::use(rawData);
}

void
saveManifests(
    soci::session& session,
    std::string const& dbTable,
    std::function<bool(PublicKey const&)> const& isTrusted,
    hash_map<PublicKey, Manifest> const& map,
    beast::Journal j)
{
    soci::transaction tr(session);
    session << "DELETE FROM " << dbTable;
    for (auto const& v : map)
    {
        // Save all revocation manifests,
        // but only save trusted non-revocation manifests.
        if (!v.second.revoked() && !isTrusted(v.second.masterKey))
        {
            JLOG(j.info()) << "Untrusted manifest in cache not saved to db";
            continue;
        }

        saveManifest(session, dbTable, v.second.serialized);
    }
    tr.commit();
}

void
addValidatorManifest(soci::session& session, std::string const& serialized)
{
    soci::transaction tr(session);
    saveManifest(session, "ValidatorManifests", serialized);
    tr.commit();
}

void
clearNodeIdentity(soci::session& session)
{
    session << "DELETE FROM NodeIdentity;";
}

std::pair<PublicKey, SecretKey>
getNodeIdentity(soci::session& session)
{
    {
        // SOCI requires boost::optional (not std::optional) as the parameter.
        boost::optional<std::string> pubKO, priKO;
        soci::statement st =
            (session.prepare
                 << "SELECT PublicKey, PrivateKey FROM NodeIdentity;",
             soci::into(pubKO),
             soci::into(priKO));
        st.execute();
        while (st.fetch())
        {
            auto const sk = parseBase58<SecretKey>(
                TokenType::NodePrivate, priKO.value_or(""));
            auto const pk = parseBase58<PublicKey>(
                TokenType::NodePublic, pubKO.value_or(""));

            // Only use if the public and secret keys are a pair
            if (sk && pk && (*pk == derivePublicKey(KeyType::secp256k1, *sk)))
                return {*pk, *sk};
        }
    }

    // If a valid identity wasn't found, we randomly generate a new one:
    auto [newpublicKey, newsecretKey] = randomKeyPair(KeyType::secp256k1);

    session << str(
        boost::format("INSERT INTO NodeIdentity (PublicKey,PrivateKey) "
                      "VALUES ('%s','%s');") %
        toBase58(TokenType::NodePublic, newpublicKey) %
        toBase58(TokenType::NodePrivate, newsecretKey));

    return {newpublicKey, newsecretKey};
}

std::unordered_set<PeerReservation, beast::uhash<>, KeyEqual>
getPeerReservationTable(soci::session& session, beast::Journal j)
{
    std::unordered_set<PeerReservation, beast::uhash<>, KeyEqual> table;
    // These values must be boost::optionals (not std) because SOCI expects
    // boost::optionals.
    boost::optional<std::string> valPubKey, valDesc;
    // We should really abstract the table and column names into constants,
    // but no one else does. Because it is too tedious? It would be easy if we
    // had a jOOQ for C++.
    soci::statement st =
        (session.prepare
             << "SELECT PublicKey, Description FROM PeerReservations;",
         soci::into(valPubKey),
         soci::into(valDesc));
    st.execute();
    while (st.fetch())
    {
        if (!valPubKey || !valDesc)
        {
            // This represents a `NULL` in a `NOT NULL` column. It should be
            // unreachable.
            continue;
        }
        auto const optNodeId =
            parseBase58<PublicKey>(TokenType::NodePublic, *valPubKey);
        if (!optNodeId)
        {
            JLOG(j.warn()) << "load: not a public key: " << valPubKey;
            continue;
        }
        table.insert(PeerReservation{*optNodeId, *valDesc});
    }

    return table;
}

void
insertPeerReservation(
    soci::session& session,
    PublicKey const& nodeId,
    std::string const& description)
{
    auto const sNodeId = toBase58(TokenType::NodePublic, nodeId);
    session << "INSERT INTO PeerReservations (PublicKey, Description) "
               "VALUES (:nodeId, :desc) "
               "ON CONFLICT (PublicKey) DO UPDATE SET "
               "Description=excluded.Description",
        soci::use(sNodeId), soci::use(description);
}

void
deletePeerReservation(soci::session& session, PublicKey const& nodeId)
{
    auto const sNodeId = toBase58(TokenType::NodePublic, nodeId);
    session << "DELETE FROM PeerReservations WHERE PublicKey = :nodeId",
        soci::use(sNodeId);
}

bool
createFeatureVotes(soci::session& session)
{
    soci::transaction tr(session);
    std::string sql =
        "SELECT count(*) FROM sqlite_master "
        "WHERE type='table' AND name='FeatureVotes'";
    // SOCI requires boost::optional (not std::optional) as the parameter.
    boost::optional<int> featureVotesCount;
    session << sql, soci::into(featureVotesCount);
    bool exists = static_cast<bool>(*featureVotesCount);

    // Create FeatureVotes table in WalletDB if it doesn't exist
    if (!exists)
    {
        session << "CREATE TABLE  FeatureVotes ( "
                   "AmendmentHash      CHARACTER(64) NOT NULL, "
                   "AmendmentName      TEXT, "
                   "Veto               INTEGER NOT NULL );";
        tr.commit();
    }
    return exists;
}

void
readAmendments(
    soci::session& session,
    std::function<void(
        boost::optional<std::string> amendment_hash,
        boost::optional<std::string> amendment_name,
        boost::optional<AmendmentVote> vote)> const& callback)
{
    // lambda that converts the internally stored int to an AmendmentVote.
    auto intToVote = [](boost::optional<int> const& dbVote)
        -> boost::optional<AmendmentVote> {
        return safe_cast<AmendmentVote>(dbVote.value_or(1));
    };

    soci::transaction tr(session);
    std::string sql =
        "SELECT AmendmentHash, AmendmentName, Veto FROM "
        "( SELECT AmendmentHash, AmendmentName, Veto, RANK() OVER "
        "(  PARTITION BY AmendmentHash ORDER BY ROWID DESC ) "
        "as rnk FROM FeatureVotes ) WHERE rnk = 1";
    // SOCI requires boost::optional (not std::optional) as parameters.
    boost::optional<std::string> amendment_hash;
    boost::optional<std::string> amendment_name;
    boost::optional<int> vote_to_veto;
    soci::statement st =
        (session.prepare << sql,
         soci::into(amendment_hash),
         soci::into(amendment_name),
         soci::into(vote_to_veto));
    st.execute();
    while (st.fetch())
    {
        callback(amendment_hash, amendment_name, intToVote(vote_to_veto));
    }
}

void
voteAmendment(
    soci::session& session,
    uint256 const& amendment,
    std::string const& name,
    AmendmentVote vote)
{
    soci::transaction tr(session);
    std::string sql =
        "INSERT INTO FeatureVotes (AmendmentHash, AmendmentName, Veto) VALUES "
        "('";
    sql += to_string(amendment);
    sql += "', '" + name;
    sql += "', '" + std::to_string(safe_cast<int>(vote)) + "');";
    session << sql;
    tr.commit();
}

}  // namespace ripple
